KR100994969B1 - Method for distributing light, light-distributing cup and street lamp adopting the same - Google Patents

Abstract

The light distribution method of the present invention causes a part of the light emitted by the light source to be emitted directly from the light distribution cup, and causes the remaining part of the light to be emitted to the inner wall of the light distribution cup, and also to be reflected from the light distribution cup. The light emitted directly to the outside forms a rectangular chief light point therein, and then first combines with the emitted light that is emitted to the inner wall and reflected by the light distribution cup to form a rectangular overlapping light point corresponding to the shape of the chief light point. do. Accordingly, a more even light spot can be generated, and the quantity of street lamps can be made economical, which is useful for the design of street lamps or related lighting fixtures.

Description

Light distribution method, light distribution cup and street light using the same {METHOD FOR DISTRIBUTING LIGHT, LIGHT-DISTRIBUTING CUP AND STREET LAMP ADOPTING THE SAME}

The present invention relates to a method of designing a path of light, and more particularly to a distribution light method. The invention also relates to a lighting accessory, in particular a light distributing cup, and also to a street lamp using the light distribution cup.

The street lamp generally includes a lamp pole, a lamp head portion installed on the lamp pillar, a light distribution cup provided in the lamp head portion, and a light source provided in the light distribution cup. Light emitted by a point light source provides Lambert radiation in three-dimensional space. In general, for the dedicated use of road lighting, downward flooding is sufficient. Therefore, the main function of the light distribution cup is to reflect such upward or horizontal light emitted by the point light source downward to improve the light efficiency. Conventional light distribution cups and lights that are horn shaped will pass through this light distribution cup and form a round light spot. The reflecting wall of such a light distribution cup is not an ideal design, which allows only a part of the light to be emitted from the light distribution cup after two or several reflections, and even some of the light is ultimately not reflected to the outside, resulting in waste of light energy. Also, since these light cups form a round light spot when they are emitted on the road, some of the light emitted from the light cup will be emitted over the road, and another part of the light overlaps with that emitted by the street lamps on the other side of the road. Will cause a waste of light energy. On the other hand, since the light of the street lamp can be distributed only in a small range, it is required that more street lights are installed within a unit distance to ensure successful brightness on the road.

It is therefore an object of the present invention to provide a light distribution method which solves the above-described problems, which can transform light in the form of Lambert radiation emitted by a point light source into even rectangular light spots.

The above mentioned objects can be achieved by the following technical solutions:

A light distribution method is one in which a part of the light emitted by the light source is emitted directly from the light distribution cup, and the remaining part of the light emitted by the light source is emitted to the inner wall of the light distribution cup and then reflected from the light distribution cup. A portion of the light that is directly emitted to the outside forms a rectangular chief point. First, the remaining portion of the light emitted to the inner wall and reflected by the light distribution cup forms a rectangular light spot that overlaps the rectangular chief point.

Therefore, the advantages of the present invention are as follows:

The present invention is capable of transforming light emitted by a point light source into a rectangular light spot, which is preferable for use in long and narrow spaces; The light emitted by the inner wall and reflected by the light distribution cup forms a rectangular light spot that overlaps with the main light point, so that the present invention can have higher light efficiency, higher brightness, and more even light spot.

In addition, the present invention may be further improved by the following technical solutions:

The beam angle forming the main light point is a set value. The beam angle of the light reflected from the inner wall of the light distribution cup is equal to the beam angle of the main light point. The beam angle of such reflected light gradually changes from the opening of the light distribution cup to the bottom within the gradually set range. As mentioned above, the beam angle forming the main light spot is a set value, and the relationship between the distance between the light source and the light projecting body and the dimension of the light spot can be calculated according to Pythagorean theorem, whereby the light brightness and the light projecting area can be determined. have. On the other hand, the beam angle of the light reflected from the opening of the light distribution cup is equal to the beam angle of the main light point, and the beam angle of the reflected light is gradually changed from the opening of the light distribution cup to the bottom within the set range, so that the light points may overlap at the dark circumference of the main light point. The light spot becomes more even.

The beam angle of the light emitted on the inner wall of the light distribution cup varies uniformly from the opening of the light distribution cup to the bottom.

In the longitudinal direction of the light distribution cup, the beam angle of the main light point is 30 °, and the beam angle of the reflected light emitted on the inner wall of the light distribution cup gradually changes from 30 ° to 0 °, while in the horizontal direction of the light distribution cup, the beam angle of the main light point is 62 ° and the beam angle of the reflected light emitted to the inner wall of the light distribution cup is gradually changed from 62 ° to 30 °, so that a light spot of 40 × 12 m may be generated when the distance between the light source and the light projector is 12 m.

It is still another object of the present invention to provide a light distribution cup capable of transforming light emitted by a point light source into a rectangular light spot having higher light efficiency, higher brightness and more even transmittance.

This object is achieved by the following technical solution:

The light distribution cup includes a bottom wall and a side wall, and a reflective layer is provided on the inner surface of both the bottom wall and the side wall, the bottom portion is rectangular, the inner surface of the light distribution cup is curved and concave inward, and the side walls surround the cup body circumferentially. Provided to form a rectangular opening.

An advantage of the present invention is that the rectangular openings of the light distribution cup can produce rectangular light spots, allowing the present invention to be used in long and narrow spaces, and the light emitted from the light distribution cup to be rectangular. On the other hand, the inner surface of the side wall is concave inward, and by forming a rectangular opening circumferentially surrounding the cup body, the reflected light can form a rectangular light point similar to the main light point. The light spot formed by the reflected light overlaps with the main light spot, resulting in higher brightness and light efficiency and more even light spot.

Preferably, the main beam angle is a set value, and the concave curved surface of the side wall is a free curved surface calculated by Snell's Law. The beam angle of the light reflected from the opening of the cup is the same as the main beam angle. The beam angle of the reflected light gradually changes from the opening of the light distribution cup to the bottom within the set range.

Preferably, the structure of the sidewalls causes the beam angle of the reflected light to vary uniformly from the opening of the light distribution cup to the bottom.

Preferably, in the longitudinal direction of the light distribution cup, the beam angle of the chief light point is 30 °, while the beam angle of the reflected light varies gradually within 30 ° to 0 ° from the opening to the bottom.

Preferably, in the transverse direction of the light distribution cup, the beam angle of the chief light point is 62 °, while the beam angle of the reflected light varies gradually within 62 ° to 30 ° from the opening to the bottom.

Preferably, the light source mounting hole is provided at the bottom center of the light distribution cup.

Preferably, the reflective layer is a medium lamina or metal thin layer.

Alternatively, the reflective layer is an aluminum coating layer.

It is a further object of the present invention to provide a street lamp which can produce a rectangular light spot on the ground with higher brightness and more even transmissivity.

This object is achieved by the following technical solution:

The street light includes a lamp post, a light distribution cup mounted in the lamp head portion, and a light source provided in the light distribution cup, the light distribution cup is a cup as described above, and the longitudinal direction of the light distribution cup is parallel to the road.

The advantage of the present invention is that, in comparison with the conventional round light spot, the light distribution cup of the present invention can produce a rectangular light spot with higher brightness and more even light transmittance under the same light intensity, thereby extending the distance between the two street lamps longer. will be. Therefore, the quantity of street lights installed on the road within the unit length can be reduced to satisfy the power consumption.

Preferably, a plurality of light distribution cups are provided above the lamp posts, and a light source is provided in each light distribution cup.

Preferably, the light distribution cups are arranged in an array or fixedly arranged.

Preferably, the light source is a high power LED.

1 and 2, the light distribution cup 1 is a rectangular cavity. The bottom part 11 provided with the light source mounting hole in the center is rectangular. In the present invention, the light source is preferably a point light source 14 capable of emitting light in the form of Lambert radiation. The point light source 14 may be a known light source such as a high power LED, a tungsten lamp or a fluorescent lamp. Side walls 12 and 13 surround the bottom of the cup to form a rectangular opening. The reflective layer is provided on the bottom 11 and the surfaces of the side walls 12 and 13. The reflective layer may be a thin layer medium (ie TiO ₂ , SiO ₂ or MgF ₂ ) or a thin metal layer (ie aluminum coating or silver coating), or the surface of the bottom 11 and the side walls 12, 13 to obtain a suitable reflective effect. It can be obtained by direct polishing. Any other method that can be curved to achieve this reflective effect can also be employed.

The side walls 12 and 13 are designed to reflect light emitted by the point light source 14 at the center of the bottom portion 11 from the light distribution cup 1 to the outside only once, inside the light distribution cup 1. Avoids waste of light energy due to repeated light reflections. This can be achieved by accurately designing the angles formed by the side walls 12, 13 and bottom 11 according to Snell's law. However, in order to adjust the angle of the reflected light changing in a small range, it is necessary to design the side walls 12 and 13 as concave curves to adjust the shape of the light spot generated by the light distribution cup 1 and the brightness of the light spot in each region. desirable.

The structure and design principle of the light distribution cup 1 are the origin of the two-dimensional coordinate system having a vertical direction as the Y axis and a horizontal direction as the X axis, where the light source 14 is located. For example, as shown in FIGS. 3B and 4, it is described below as having the sidewall 13 in the longitudinal direction shown as an example. The beam angle of the main light point is the widest angle between the light emitted directly from the light distribution cup to the outside and the axis of the light distribution cup (the X axis in FIG. 4). That is, the angle is formed by the light that is accurately emitted through the boundary surface of the light distribution cup and the axis of the light distribution cup. The beam angle of the main light point greatly affects the shape and brightness of the light spot. If the distance between the light source 14 and the light-transmitter is constant, as the beam angle becomes wider, the area of the light spot becomes larger accordingly, and the light intensity becomes conversely lower, and when the beam angle becomes narrower, the area of the light spot becomes It becomes smaller and the light intensity becomes higher. Designers can calculate the beam angle according to the Pyragora's theorem in practical applications. For example, when the present invention is applied to a street light, the beam angle is 30 °, the height to be installed is 12m, and the width of the light spot is 13.8m.

The beam angle of the reflected light is an angle formed by an arbitrary reflected light emitted to the inner wall 13 of the light distribution cup 1 and the axis of the light distribution cup 1. In the present invention, the light is reflected by the side wall 13, so that the light spot formed by the reflected light has a form similar to that of the main light spot. Accordingly, the beam angle of each light reflected by the side wall 13 is adjusted by the curved state of the light distribution cup 1, and thus the shape and brightness of the light spot are adjusted, whereby the light spot is added to the dark region of the main light spot. It can make it possible to achieve more even brightness. The widest beam angle is the angle between the reflected light emitted at the top point of the sidewall 13 and the axis of the light distribution cup. It is an object of the present invention to add a light spot to the dark circumference of the main light spot. The widest beam angle should be the same as the beam angle of the main light point, so that light emitted at the left edge of the opening of the light distribution cup can be reflected to the rightmost edge of the main light point. Therefore, the beam angle of the light reflected by the inner wall under the opening of the light distribution cup decreases at a geometric ratio, the reflected light moves inside the main light point, so that the intensity of the light spot is stronger from the outside to the inside, and ultimately the overall brightness is higher. Evenly.

The light reflecting surface that realizes the above-mentioned reflection effect is a free surface calculated by Snell's law and the integral iternative method. Referring to Figure 4, the curved cross-section curve should satisfy the following equation:

For example, the coordinates of the points on the curve are determined according to the following factors: the height of the side wall 13 (Y axis of the opening of the light distribution cup) is 10 mm, the width of the bottom of the light distribution cup is 6 mm, and the beam angle of the main light point is Is 30 °, and the beam angle of the reflected light emitted on the sidewall 13 of the light distribution cup is gradually changed within 30 ° to 0 ° from the opening of the light distribution cup to the bottom at the geometrical ratio. The height of the side walls is divided into 1000 integral points. Accordingly,

Wherein n is the present point of the calculated numerical value, n + 1 is the succeeding point of the calculated numerical value, and Δx and Δy are variable micro quantum in the x and y axis directions. Based on the initial state,

From the bottom up the coordinates of each point can be calculated by the integral iteration method according to the equations listed above, for example the coordinates of the first point are (3.00577, 0.01) and the coordinates of the second point are (3.01152, 0.02) , The coordinate of the third point is (3.01725, 0.03), ......, the coordinate of the last point is (5.77350, 10). In this embodiment, it is divided into 1000 integral points in the Y-axis direction, which can be enlarged or reduced according to actual accuracy requirements. Similarly, so is the free curved surface of the side wall in the transverse direction of the light distribution cup. The beam angle of the main light spot in the transverse direction of the light distribution cup is 62 °, and the beam angle of the reflected light radiated on the sidewall 13 of the light distribution cup varies gradually from 62 ° to 30 ° from the opening to the bottom at a geometric ratio. When such a light distribution cup 1 is installed at a height of 12m, an even rectangular light spot of 40m x 13.8m can be obtained. The calculation of points can be terminated by computer software, which then connects each point to a smooth surface. The model is then established by computer drawing software, and finally, manufacturing is performed by digitally controlled machining or precision casting.

Referring to FIG. 5, in the first embodiment of the street lamp using the light cup 1 described above, the light cup 1 is mounted on top of the lamp post 2 and may be a high pressure sodium lamp or a high power LED. The light source 14 is provided in the light distribution cup 1, and the longitudinal direction of the light distribution cup is parallel to the road. Compared with the conventional round light spot, the light distribution cup of the present invention can produce a rectangular light spot having higher brightness and more even light transmittance under the same light intensity, thereby making the placement distance between the two street lights wider. Accordingly, the number of street lights installed on the road within the unit length can be reduced to satisfy the power consumption. In addition, the reflective panel 15 having a diffusion structure may be provided on the front surface of the light distribution cup so that the passerby does not feel dizzy.

6, 7 and 8, in another embodiment of a street lamp, the lamp head portion 3 is mounted on top of the lamp post, and a plurality of light distribution cups 1 are provided on the lamp head portion 3. A light source 14 is provided in each light distribution cup 1, the longitudinal direction of all the light distribution cups is parallel to the road, and the plurality of light distribution cups 1 are interlaced as shown in FIG. It may be arranged in an array as shown in FIG.

The size and brightness of the light spot is related to the quantity of LEDs. Various installation heights and test data for street lamps with different quantities of LEDs of the present invention, which the user can freely select according to actual application, are as follows:

In the table, luminous flux was tested in either street light, the applied LED power was 1W, and the luminous flux of each LED was 70 to 80 lm.

Further features and advantages of the present invention will become apparent from the following description presented as non-limiting examples, which are described in connection with the accompanying drawings.

1 is a schematic diagram of a light distribution cup structure according to a preferred embodiment of the present invention.

2 is a schematic cross-sectional view of an inner wall of a light distribution cup according to a preferred embodiment of the present invention.

Figure 3a is a schematic view showing a light distribution cup of the present invention that reflects light in the horizontal direction.

Figure 3b is a schematic view showing a light distribution cup of the present invention that reflects light in the longitudinal direction.

4 is a mathematical model of the cross-sectional curve of the side wall curved surface of the light distribution cup of the present invention.

5 is a schematic diagram of a street lamp structure according to a first embodiment of the present invention.

6 is a first schematic diagram of a street lamp structure according to a second embodiment of the present invention.

7 is a second schematic diagram of a lamp head portion structure according to the second embodiment of the present invention.

8 is a third schematic diagram of a lamp head portion structure according to the second embodiment of the present invention.

(Short description of the main reference signs)

1: light distribution cup 2: lamp post

3: head portion 11: bottom portion

12, 13: sidewall 14: light source

15: reflective panel

Claims (22)

delete delete delete delete delete Bottom; Sidewalls; And A reflective layer provided on the inner surface of both the bottom and the sidewalls, The bottom part is rectangular, and the inner surface of the side wall in the longitudinal direction is formed by bending concave inwardly so that the beam angle of the main light point is 30 °, and the beam angle of the reflected light is gradually changed from 30 to 0 ° from the opening to the bottom. And the inner wall of the side wall is formed by bending concave inwardly so that the beam angle of the main light point is 62 ° and the beam angle of the reflected light is gradually changed from 62 to 30 ° from the opening to the bottom. delete delete delete delete The light distribution cup according to claim 6, wherein the light source mounting hole is provided at the center of the bottom of the light distribution cup. The light distribution cup of claim 6 wherein the reflective layer is a medium lamina or a thin metal layer. The light distribution cup of claim 12, wherein the reflective layer is an aluminum coating layer. Lamp posts; A light distribution cup installed on an upper part of the lamp post; And It includes a light source provided in the light distribution cup, The bottom of the light distribution cup has a rectangular shape, and the inner sidewall of the longitudinal sidewall is formed by concave inwardly so that the beam angle of the main light point is 30 °, and the beam angle of the reflected light is gradually changed from 30 to 0 ° from the opening to the bottom. The inner surface of the side wall in the horizontal direction is formed by bent concave inward so that the beam angle of the main light point is 62 ° and the beam angle of the reflected light is gradually changed from 62 ° to 30 ° from the opening to the bottom. Parallel street lamps. delete delete delete delete 15. The streetlight of claim 14, wherein a plurality of light distribution cups are provided on top of the lamp posts, and a light source is provided in each light distribution cup. 20. The streetlight of claim 19, wherein the plurality of light distribution cups are arranged in an array or interlaced. The street light of claim 14 wherein the light source is a high power LED. The street lamp according to claim 14, wherein a light distribution panel is provided on the front surface of the light distribution cup.

Images